Here is a brief list of the astounding predictions of the COI model, just to whet your appetite
for what you’ll find in “Where Time Begins”:
Classical mechanics, interwoven with time dilation, generates a redshift profile from the proposed COI initial state that matches, within experimental accuracy, what we see
today.
This establishes the Milky Way galaxy as close to the centre of the
universe.
It explains why we can see galaxies 14 billion light years away though the age of the Milky Way is only about 1 to 2 billion years
old.
It determines the gravitational profile of the universe from the MGR curves. These curves are simple geometric constraints flowing from the speed of gravity as the speed of
light.
This quite reasonably assumes or justifies the use of classical gravity because of the very,
very small gravitational field strengths involved. This is not a new theory
of gravity or laws of physics, it is just the result of the evolution of gravity from the start of time.
Other models tend to skip this evolution by assuming an infinite, homogeneous, steady state universe. These other models also require hypothetical need new entities of dark matter and dark energy to explain serious
problems.
This demonstrates that the gravity profile is proportional to
time using algebraic approximations. It shows that gravitational forces near the centre of the universe causes the observed linear recession velocity profile in near ranges. (This is so obvious, it's
embarrassing!)
A simple integration of the g profile over time and over space predicts speed and gravitational potential. These in turn predict the Doppler and Gravitational redshift
components.
Plots of galactic redshifts from 100’s, even
thousands of entries in the NASA Extragalactic Database (NED) show that the COI model predictions better meet experimental observation than Hubble’s Law (H0) especially in near range and far range.
It shows that the near range improvements do away with the need for a lot of ‘peculiar’
velocities.
It shows that the far range predictions explain the drop off in z, and you don’t have to assume the rate of expansion of the universe is
changing.
It shows that the gravitational redshift component, which is really time dilation, better explains and predicts the observed stretching of Super Nova Type Ia light
curves.
It’s well known that distance versus redshift seems to lose its proportionality above z=0.1. Amazingly, the COI algorithm predicts a change from primarily Doppler redshift to primarily gravitational redshift at z=0.1
The COI model predicts the age of distant galaxies (13 Gly)
to be about 800 Myr. This is a number accepted by the expanding universe model when looking at Hubble ultra-deep-view Space
photos. Yet its prediction of ages around 1 to 2 billion years for near range galaxies seems challenging until you recognised that it solves problems like the galactic windup dilemma.
The fingers of god effect is another problem that the exclusively radial forces of the COI model seems to
explain.
The COI simulator generates estimates of redshift changes brought on by density variations in clusters. These estimates are directly in line with peculiar velocities previously attributed to gravitational in-fall.
In the 1.0.2 release, (2020/11/30), I was able to explain the Cosmic Microwave Background (CMB) radiation.
The 1.0.2 software release also explains the KBC void; the largest structure ever detected in the universe.